Role of Vector in Activation of T Cell Subsets in Immune Responses against the Secreted Transgene Product Factor IX

Defining immune responses against the secreted transgene product in a gene therapy setting is critical for treatment of genetic diseases such as hemophilia B (coagulation factor IX deficiency). We have previously shown that intramuscular administration of an adeno-associated viral (AAV) vector results in stable expression of therapeutic levels of factor IX (F.IX) and may be associated with humoral immune responses against F.IX. This study demonstrates that intramuscular injection of an AAV vector expressing F.IX fails to activate F.IX-specific cytotoxic T lymphocytes (CTLs) in hemostatically normal or in hemophilia B mice, so that there is an absence of cellular immune responses against F.IX. However, transgene-derived F.IX can cause B cell responses characterized by production of T helper cell-dependent antibodies (predominantly IgG1, but also IgG2 subclasses) resulting from activation of CD4⁺ T helper cells primarily of the Th2 subset. In contrast, administration of an adenoviral vector efficiently activated F.IX-specific CTLs and T helper cells of both Th1 and Th2 subsets, leading to inflammation and destruction of transduced muscle tissue and activation of B cells as well. Therefore, vector sequences fundamentally influence T cell responses against transgene-encoded F.IX. In conclusion, activation of the immune system in AAV-mediated gene transfer is restricted to pathways mediated by F.IX antigen presentation through MHC class II determinants resulting in T and B cell responses that are more comparable to responses in the setting of protein infusion rather than of viral infection/gene transfer.     

Induction of immune tolerance to coagulation factor IX antigen by in vivo hepatic gene transfer

Gene replacement therapy is an attractive approach for treatment of genetic disease, but may be complicated by the risk of a neutralizing immune response to the therapeutic gene product. There are examples of humoral and cellular immune responses against the transgene product as well as absence of such responses, depending on vector design and the underlying mutation in the dysfunctional gene. It has been unclear, however, whether transgene expression can induce tolerance to the therapeutic antigen. Here, we demonstrate induction of immune tolerance to a secreted human coagulation factor IX (hF.IX) antigen by adeno-associated viral gene transfer to the liver. Tolerized mice showed absence of anti-hF.IX and substantially reduced in vitro T cell responses after immunization with hF.IX in adjuvant. Tolerance induction was antigen specific, affected a broad range of Th cell subsets, and was favored by higher levels of transgene expression as determined by promoter strength, vector dose, and mouse strain. Hepatocyte-derived hF.IX expression induced regulatory CD4(+) T cells that can suppress anti-hF.IX formation after adoptive transfer. With a strain-dependent rate of success, tolerance to murine F.IX was induced in mice with a large F.IX gene deletion, supporting the relevance of these data for treatment of hemophilia B and other genetic diseases.     

Muscle as a target for supplementary factor IX gene transfer

Immune responses to the factor IX (F.IX) transgene product are a concern in gene therapy for the X-linked bleeding disorder hemophilia B. The risk for such responses is determined by several factors, including the vector, target tissue, and others. Previously, we have demonstrated that hepatic gene transfer with adeno-associated viral (AAV) vectors can induce F.IX-specific immune tolerance. Muscle-derived F.IX expression, however, is limited by a local immune response. Here, skeletal muscle was investigated as a target for supplemental gene transfer. Given the low invasiveness of intramuscular injections, this route would be ideal for secondary gene transfer, thereby boosting levels of transgene expression. However, this is feasible only if immune tolerance established by compartmentalization of expression to the liver extends to other sites. Immune tolerance to human F.IX established by prior hepatic AAV-2 gene transfer was maintained after subsequent injection of AAV-1 or adenoviral vector into skeletal muscle, and tolerized mice failed to form antibodies or an interferon (IFN)-gamma(+) T cell response to human F.IX. A sustained increase in systemic transgene expression was obtained for AAV-1, whereas an increase after adenoviral gene transfer was transient. A CD8(+) T cell response specifically against adenovirus-transduced fibers was observed, suggesting that cytotoxic T cell responses against viral antigens were sufficient to eliminate expression in muscle. In summary, the data demonstrate that supplemental F.IX gene transfer to skeletal muscle does not break tolerance achieved by liver-derived expression. The approach is efficacious, if the vector for muscle gene transfer does not express immunogenic viral proteins.     

Major role of local immune responses in antibody formation to factor IX in AAV gene transfer

The risk of an immune response to the coagulation factor IX (F.IX) transgene product is a concern in gene therapy for the X-linked bleeding disorder hemophilia B. In order to investigate the mechanism of F.IX-specific lymphocyte activation in the context of adeno-associated viral (AAV) gene transfer to skeletal muscle, we injected AAV-2 vector expressing human F.IX (hF.IX) into outbred immune-competent mice. Systemic hF.IX levels were transiently detected in the circulation, but diminished concomitant with activation of CD4+ T and B cells. ELISPOT assays documented robust responses to hF.IX in the draining lymph nodes of injected muscle by day 14. Formation of inhibitory antibodies to hF.IX was observed over a wide range of vector doses, with increased doses causing stronger immune responses. A prolonged inflammatory reaction in muscle started at 1.5-2 months, but ultimately failed to eliminate transgene expression. By 1.5 months, hF.IX antigen re-emerged in circulation in approximately 70% of animals injected with high vector dose. Hepatic gene transfer elicited only infrequent and weaker immune responses, with higher vector doses causing a reduction in T-cell responses to hF.IX. In summary, the data document substantial influence of target tissue, local antigen presentation, and antigen levels on lymphocyte responses to F.IX.     

Therapeutic levels of factor IX expression using a muscle-specific promoter and adeno-associated virus serotype 1 vector

Extensive studies in animal models of the X-linked bleeding disorder hemophilia B (deficiency in functional coagulation factor IX, F.IX) have shown that muscle-directed adeno-associated (AAV)-mediated F.IX gene transfer can be used to treat this disease. However, large vector doses of AAV-2 vector are required for therapeutic levels of expression, and the number of vector doses that can be injected per intramuscular site is limited. Several studies have shown that some of these limitations can be overcome by use of AAV serotype 1 vector. Here, we demonstrate levels of F.IX transgene expression from a synthetic muscle-specific promoter (C5-12) that were higher than from the cytomegalovirus (CMV) immediate-early enhancer-promoter in cultured muscle cells in vitro and approximately 50% of CMV-driven expression in vivo in murine skeletal muscle after AAV-1 gene transfer. These data show for the first time that a tissue-specific promoter can be used to achieve therapeutic levels of muscle-derived F.IX expression in the context of viral gene transfer. However, use of a muscle-specific promoter did not prevent antibody formation in response to a murine F.IX transgene product in mice with F.IX gene deletion, indicating that the risk of humoral immune responses remains in the context of an immunologically unfavorable mutation.     

Nonredundant Roles of IL-10 and TGF-�� in Suppression of Immune Responses to Hepatic AAV-Factor IX Gene Transfer

Hepatic gene transfer using adeno-associated viral (AAV) vectors has been shown to efficiently induce immunological tolerance to a variety of proteins. Regulatory T-cells (Treg) induced by this route suppress humoral and cellular immune responses against the transgene product. In this study, we examined the roles of immune suppressive cytokines interleukin-10 (IL-10) and transforming growth factor-β (TGF-β) in the development of tolerance to human coagulation factor IX (hF.IX). Interestingly, IL-10 deficient C57BL/6 mice receiving gene transfer remained tolerant to hF.IX and generated Treg that suppressed anti-hF.IX formation. Effects of TGF-β blockade were also minor in this strain. In contrast, in C3H/HeJ mice, a strain known to have stronger T-cell responses against hF.IX, IL-10 was specifically required for the suppression of CD8⁺ T-cell infiltration of the liver. Furthermore, TGF-β was critical for tipping the balance toward an regulatory immune response. TGF-β was required for CD4⁺CD25⁺FoxP3⁺ Treg induction, which was necessary for suppression of effector CD4⁺ and CD8⁺ T-cell responses as well as antibody formation. These results demonstrate the crucial, nonredundant roles of IL-10 and TGF-β in prevention of immune responses against AAV-F.IX-transduced hepatocytes.     

AAV-mediated gene transfer for the treatment of hemophilia B: problems and prospects

Adeno-associated viral vector-mediated gene transfer of coagulation factor IX to the skeletal muscle or to liver has resulted in sustained correction of hemophilia B in mice and dogs. The two initial phase I/II AAV clinical trials for hemophilia B, delivering a factor IX cDNA to skeletal muscle or liver, showed no serious adverse events. Although the muscle trial failed to achieve a therapeutic level of factor IX in the circulation, long-term expression of clotting factor was demonstrated on muscle biopsies taken up to 3 years after vector injection. Administration of vector to liver via the hepatic artery identified a therapeutic dose, which agreed closely with the doses predicted by studies in hemophilic dogs. However, expression in human subjects lasted for only a period of weeks, followed by a gradual decline in factor IX levels accompanied by a self-limited, asymptomatic rise and fall in liver enzymes. Immune responses to vector capsid may account for this difference in outcome between humans and other species. Here we review the results from both preclinical and clinical studies of adeno-associated viral vector gene transfer for hemophilia B, and the problems that have been identified and that must be overcome to achieve successful transduction and sustained expression.     

A Preclinical Animal Model to Assess the Effect of Pre-existing Immunity on AAV-mediated Gene Transfer

Hepatic adeno-associated virus (AAV)-serotype 2–mediated gene transfer results in sustained transgene expression in experimental animals but not in human subjects. We hypothesized that loss of transgene expression in humans might be caused by immune memory mechanisms that become reactivated upon AAV vector transfer. Here, we tested the effect of immunological memory to AAV capsid on AAV-mediated gene transfer in a mouse model. Upon hepatic transfer of an AAV2 vector expressing human factor IX (hF.IX), mice immunized with adenovirus (Ad) vectors expressing AAV8 capsid before AAV2 transfer developed less circulating hF.IX and showed a gradual loss of hF.IX gene copies in liver cells as compared to control animals. This was not observed in mice immunized with an Ad vectors expressing AAV2 capsid before transfer of rAAV8-hF.IX vectors. The lower hF.IX expression was primarily linked to AAV-binding antibodies that lacked AAV-neutralizing activity in vitro rather than to AAV capsid–specific CD8⁺ T cells.     

Tolerance induction by viral in vivo gene transfer

Treatment of genetic disease by protein or gene replacement therapy is hampered by immune responses to the therapeutic protein. An excellent example is formation of inhibitory antibodies to coagulation factors in treatment of the X-linked bleeding disorder hemophilia. Experiments in murine and canine models of hemophilia B (deficiency in factor IX) have demonstrated sustained therapeutic levels of factor IX transgene expression following hepatic adeno-associated viral gene transfer in animals with deletion and nonsense mutations in the factor IX gene. This article reviews experimental evidence for induction of immune tolerance to the factor IX transgene product by hepatic adeno-associated viral gene transfer, which has been shown to limit T helper cell responses and to substantially reduce the risk of antibody responses. Tolerance induction is associated with activation of regulatory CD4(+) T cells capable of suppressing antibody formation to factor IX protein. Hepatic administration of adeno-associated viral vector expressing ovalbumin in mice transgenic for a T cell receptor specific for this antigen provided direct evidence for induction of CD4(+) T cell tolerance, including T cell anergy and clonal deletion. Taken together, these data indicate the potential for viral in vivo gene transfer not only to provide sustained systemic expression, but moreover to induce immunological hypo-responsiveness to the therapeutic gene product.     

High-efficiency Transduction and Correction of Murine Hemophilia B Using AAV2 Vectors Devoid of Multiple Surface-exposed Tyrosines

Elimination of specific surface-exposed single tyrosine (Y) residues substantially improves hepatic gene transfer with adeno-associated virus type 2 (AAV2) vectors. Here, combinations of mutations in the seven potentially relevant Y residues were evaluated for further augmentation of transduction efficiency. These mutant capsids packaged viral genomes to similar titers and retained infectivity. A triple-mutant (Y444+500+730F) vector consistently had the highest level of in vivo gene transfer to murine hepatocytes, approximately threefold more efficient than the best single-mutants, and ~30–80-fold higher compared with the wild-type (WT) AAV2 capsids. Improvement of gene transfer was similar for both single-stranded AAV (ssAAV) and self-complementary AAV (scAAV) vectors, indicating that these effects are independent of viral second-strand DNA synthesis. Furthermore, Y730F and triple-mutant vectors provided a long-term therapeutic and tolerogenic expression of human factor IX (hF.IX) in hemophilia B (HB) mice after administration of a vector dose that only results in subtherapeutic and transient expression with WT AAV2 encapsidated vectors. In summary, introduction of multiple tyrosine-mutations into the AAV2 capsid results in vectors that yield at least 30-fold improvement of transgene expression, thereby lowering the required therapeutic dose and potentially vector-related immunogenicity. Such vectors should be attractive for treatment of hemophilia and other genetic diseases.     

Pharmacological Modulation of Humoral Immunity in a Nonhuman Primate Model of AAV Gene Transfer for Hemophilia B

Liver gene transfer for hemophilia B has shown very promising results in recent clinical studies. A potential complication of gene-based treatments for hemophilia and other inherited disorders, however, is the development of neutralizing antibodies (NAb) against the therapeutic transgene. The risk of developing NAb to the coagulation factor IX (F.IX) transgene product following adeno-associated virus (AAV)-mediated hepatic gene transfer for hemophilia is small but not absent, as formation of inhibitory antibodies to F.IX is observed in experimental animals following liver gene transfer. Thus, strategies to modulate antitransgene NAb responses are needed. Here, we used the anti-B cell monoclonal antibody rituximab (rtx) in combination with cyclosporine A (CsA) to eradicate anti-human F.IX NAb in rhesus macaques previously injected intravenously with AAV8 vectors expressing human F.IX. A short course of immunosuppression (IS) resulted in eradication of anti-F.IX NAb with restoration of plasma F.IX transgene product detection. In one animal, following IS anti-AAV6 antibodies also dropped below detection, allowing for successful AAV vector readministration and resulting in high levels (60% or normal) of F.IX transgene product in plasma. Though the number of animals is small, this study supports for the safety and efficacy of B cell-targeting therapies to eradicate NAb developed following AAV-mediated gene transfer.     

In Vivo Expansion of Regulatory T cells With IL-2/IL-2 mAb Complexes Prevents Anti-factor VIII Immune Responses in Hemophilia A Mice Treated With Factor VIII Plasmid-mediated Gene Therapy

Generation of transgene-specific immune responses can constitute a major complication following gene therapy treatment. An in vivo approach to inducing selective expansion of Regulatory T (Treg) cells by injecting interleukin-2 (IL-2) mixed with a specific IL-2 monoclonal antibody (JES6-1) was adopted to modulate anti-factor VIII (anti-FVIII) immune responses. Three consecutive IL-2 complexes treatments combined with FVIII plasmid injection prevented anti-FVIII formation and achieved persistent, therapeutic-level of FVIII expression in hemophilia A (HemA) mice. The IL-2 complexes treatment expanded CD4⁺CD25⁺Foxp3⁺ Treg cells five- to sevenfold on peak day, and they gradually returned to normal levels within 7–14 days without changing other lymphocyte populations. The transiently expanded Treg cells are highly activated and display suppressive function in vitro. Adoptive transfer of the expanded Treg cells protected recipient mice from generation of high-titer antibodies following FVIII plasmid challenge. Repeated plasmid transfer is applicable in tolerized mice without eliciting immune responses. Mice treated with IL-2 complexes mounted immune responses against both T-dependent and T-independent neoantigens, indicating that IL-2 complexes did not hamper the immune system for long. These results demonstrate the important role of Treg cells in suppressing anti-FVIII immune responses and the potential of developing Treg cell expansion therapies that induce long-term tolerance to FVIII.     

Safety of AAV Factor IX Peripheral Transvenular Gene Delivery to Muscle in Hemophilia B Dogs

Muscle represents an attractive target tissue for adeno-associated virus (AAV) vector–mediated gene transfer for hemophilia B (HB). Experience with direct intramuscular (i.m.) administration of AAV vectors in humans showed that the approach is safe but fails to achieve therapeutic efficacy. Here, we present a careful evaluation of the safety profile (vector, transgene, and administration procedure) of peripheral transvenular administration of AAV-canine factor IX (cFIX) vectors to the muscle of HB dogs. Vector administration resulted in sustained therapeutic levels of cFIX expression. Although all animals developed a robust antibody response to the AAV capsid, no T-cell responses to the capsid antigen were detected by interferon (IFN)-γ enzyme-linked immunosorbent spot (ELISpot). Interleukin (IL)-10 ELISpot screening of lymphocytes showed reactivity to cFIX-derived peptides, and restimulation of T cells in vitro in the presence of the identified cFIX epitopes resulted in the expansion of CD4⁺FoxP3⁺IL-10⁺ T-cells. Vector administration was not associated with systemic inflammation, and vector spread to nontarget tissues was minimal. At the local level, limited levels of cell infiltrates were detected when the vector was administered intravascularly. In summary, this study in a large animal model of HB demonstrates that therapeutic levels of gene transfer can be safely achieved using a novel route of intravascular gene transfer to muscle.     

Update on gene therapy for hereditary hematological disorders

The past 3 years have been characterized by a number of impressive advances as well as setbacks in gene therapy for genetic disease. Children with X-linked severe combined immunodeficiency disorder (SCID-X1) have shown almost complete reconstitution of their immune system after receiving retrovirally transduced autologous CD34⁺ hematopoietic stem cells (HSCs). However, two of 11 treated patients subsequently developed a leukemia-like disease probablydue to the undesired activation of an oncogene. Gene transfer to HSCs resulted in substantial correction of immune function and multi-lineage engraftment in two patients with adenosine deaminase (ADA)-SCID. Several Phase I clinical trials for treatment of hemophilia A and B have been initiated or completed. Partial correction of hemophilia A, albeit transient, has been reported by ex vivo gene transfer to autologous fibroblasts. Intramuscular injection of adeno-associated viral (AAV) vector to patients with severe hemophilia B resulted in evidence of Factor IX gene transfer to skeletal muscle and a separate trial based on hepatic infusion of AAV vector is ongoing. Sustained therapeutic levels of coagulation factor expression have been achieved in preclinical models using retroviral, lentiviral, AAV and high capacity adenoviral vectors. Efficient lentiviral gene transfer to HSC in murine models of β-thalassemia and sickle cell disease demonstrated sustained phenotypic correction.     

Suppression of FVIII Inhibitor Formation in Hemophilic Mice by Delivery of Transgene Modified Apoptotic Fibroblasts

The development of inhibitory antibodies to factor VIII (FVIII) is currently the most significant complication of FVIII replacement therapy in the management of patients with severe hemophilia A. Immune tolerance protocols for the eradication of inhibitors require daily delivery of intravenous FVIII for at least 6 months and are unsuccessful in 20–40% of treated patients. We hypothesize that tolerance can be induced more efficiently and reliably by delivery of FVIII antigen within autologous apoptotic cells (ACs). In this study, we demonstrated suppression of the T cell and inhibitor responses to FVIII by infusion of FVIII expression vector modified apoptotic syngeneic fibroblasts in both naive and preimmunized hemophilia A mice. ACs without FVIII antigen exerted modest generalized immune suppression mediated by anti-inflammatory signals. However, FVIII expressing apoptotic syngeneic fibroblasts produced much stronger antigen-specific immune suppression. Mice treated with these fibroblasts generated CD4⁺ T cells that suppressed the immune response to FVIII after adoptive transfer into naive recipients and antigen-specific CD4⁺CD25⁺ regulatory T cells (Tregs) that inhibited the proliferation of FVIII responsive effector T cells in vitro. These preclinical results demonstrate the potential for using FVIII vector modified autologous ACs to treat high-titer inhibitors in patients with hemophilia A.     

Induction of Immune Tolerance to FIX Following Muscular AAV Gene Transfer Is AAV-dose/FIX-level Dependent

Direct intramuscular injection (IM) of adeno-associated virus (AAV) has been proven a safe and potentially efficient procedure for gene therapy of many genetic diseases including hemophilia B. It is, however, contentious whether high antigen level induces tolerance or immunity to coagulation factor IX (FIX) following IM of AAV. We recently reported induction of FIX-specific immune tolerance by IM of AAV serotype one (AAV1) vector in mice. We hypothesize that the expression of high levels of FIX is critical to induction of FIX tolerance. In this study, we investigated the correlation among AAV dose, FIX expression, and tolerance induction. We observed that induction of immune tolerance or immunity to FIX was dependent on the dose of AAV1–human FIX (hFIX) given and the level of FIX antigen expressed in both normal and hemophilia mice. We then defined the minimum AAV1–hFIX dose and the lowest level of FIX needed for FIX tolerance. Different from hepatic AAV–hFIX gene transfer, we found that FIX tolerance induced by IM of AAV1 was not driven by regulatory T cells. These results provided further insight into the mechanism(s) of FIX tolerance, contributing to development of hemophilia gene therapy, and optimization of FIX tolerance induction protocols.     

Functions of AAV-CMV-F.IX And AAV-EF1alpha-F.IX in gene therapy for hemophilia B

There has been substantial progress in using gene therapy to treat animals with hemophilia. Adeno-associated viral (AAV) gene transfer of coagulation factor IX to skeletal muscle and liver of murine and canine models of hemophilia has resulted in sustained systemic expression and, in several studies, in complete cure of the bleeding disorder. Two AAV vectors widely used at present are AAV-CMV-F.IX and AAV-EF1alpha-F.IX. This work compares the predicted molecular functions of AAV-CMV-F.IX and AAV-EF1alpha -F.IX by sequence docking and gene ontology. It is shown that both AAV-CMV-F.IX and AAV-EF1alpha -F.IX induce coagulation factor IXa activity; however, AAV-CMV-F.IX administration also yields coagulation factor XIa activity and AAV-EF1alpha -F.IX treatment results in coagulation factor Xa activity. Therefore, AAV-CMV-F.IX might be useful for factor XI deficiency. AAV-CMV-F.IX has several additional molecular functions and processes compared with AAV-CMV-F.IX.     

DNA microarray analysis for the detection of mutations in hemophilia A

BACKGROUND: Congenital deficiency of factor (F) VIII results in the inherited X-linked bleeding disorder hemophilia A. More than 900 different mutations are reported in the hemophilia A mutation database with the largest number of mutations being single nucleotide substitutions distributed throughout the gene. Complicating the molecular characterization of this disease is the complexity of the F8 gene, the mutational heterogeneity, and technical limitations of the current mutation detection techniques. OBJECTIVE: Development of a DNA oligonucleotide microarray-based technique for F8 gene analysis to detect hemophilia A mutations. METHODS: To construct the oligonucleotide DNA microarray system: a total of 720, one base pair overlapping, 25-mer perfect match probes were designed from six exons of the F8 gene. Twenty-two different F8 gene mutations previously identified by CSGE and DNA sequence analysis were tested by using a loss-of-signal analysis approach. Differentially labeled wild type and hemophilic samples were co-hybridized to the array. Sequence alterations were detected by quantifying relative losses of test sample hybridization signals to the perfectly matched probes. RESULTS: A total of 22 different F8 mutations were tested. To test the sensitivity of the system, a blinded study was performed on 16 of the samples. F8 gene mutations can be detected with 96% efficiency with this microarray system. CONCLUSION: This proof-of-principle study has demonstrated that a F8 DNA microarray platform is an alternative gene mutation analysis approach that has a high sensitivity, and reproducibility. The methodology is, however, expensive and time consuming, and with the reduction in sequencing costs, direct sequencing is now the most cost and time efficient strategy for hemophilia A mutation analysis.     

Sustained FVIII expression and phenotypic correction of hemophilia A in neonatal mice using an endothelial-targeted sleeping beauty transposon.

Hemophilia A, deficiency of coagulation factor VIII (FVIII), is an attractive candidate for gene therapy as expression of modest amounts of FVIII can provide therapeutic benefit. Most gene transfer approaches for hemophilia have focused on the liver, as this is the major source of endogenous FVIII; however, increasing evidence suggests that endothelial cells are capable of synthesis and release of FVIII. Here the Sleeping Beauty (SB) transposon is employed to target long-term expression of the human B-domain-depleted FVIII gene (approved gene symbol F8) within lung endothelia of hemophilic mice. As the formation of inhibitory antibodies to FVIII has been a significant impediment toward achieving therapeutic plasma levels after gene or protein therapy, we chose to perform gene transfer in neonatal mice, which are more likely to be immune tolerant. Using this approach, low therapeutic levels of FVIII ( approximately 10%), as well as phenotypic correction of the bleeding disorder, were achieved in all animals that received the FVIII transposon and functional transposase throughout the duration of the study (24 weeks). Rechallenge of these animals with additional gene transfer did not result in significant increases in FVIII levels, due mainly to increases in inhibitory antibodies. These studies demonstrate the feasibility of using endothelial-targeted SB transposons for the treatment of hemophilia A.     

Long-term transgene expression from plasmid DNA gene therapy vectors is negatively affected by CpG dinucleotides.

CpG-reduced, CMV-based plasmid DNA constructs encoding human alpha-galactosidase A and factor IX were injected into C57Bl/6, BALB/c, and CD1 mice using hydrodynamics-based delivery of plasmid DNA (pDNA), and gene expression was monitored for 6 months. Linearized and supercoiled pDNAs were compared for their abilities to support long-term expression and to generate immune responses to the transgene product. In all mouse strains supercoiled CpG-reduced pDNA encoding alpha-galactosidase A and factor IX generated higher and more sustained levels of circulating gene product than their supercoiled CpG-replete analogs. Linearizing supercoiled CpG-reduced pDNA did not significantly increase levels of circulating gene product beyond levels supercoiled CpG-reduced pDNA could achieve. Linearizing supercoiled CpG-replete pDNA vectors significantly increased expression compared to their supercoiled CpG-replete analogs, but the increase was short-lived or subtherapeutic. Regardless of vector, liver depot expression did not elicit significant antibody responses to human alpha-galactosidase A or factor IX. Taken together, these data suggest that a clinically acceptable hydrodynamics-based approach targeting the liver combined with CpG-reduced pDNA vectors may represent a viable option for individuals with hemophilia, a lysosomal storage disease, or other disease in which prolonged depot expression of a therapeutic protein from the liver is desirable.